JP2015208102A - triple squirrel-cage induction motor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a highly efficient triple squirrel-cage induction motor that is adaptive to IE3 (premium efficiency).SOLUTION: A triple squirrel-cage induction motor comprises: a stator 2 that forms a rotating magnetic field; a rotor 3 rotatably provided inside the stator 2; an outer layer cage conductor 4 provided at a peripheral part of this rotor 3 and formed of a high-resistance material; an intermediate layer cage conductor 5 provided inside the outer layer cage conductor 4 and formed of a middle-resistance material; and an inner layer cage conductor 6 provided inside the intermediate layer cage conductor 5 and formed of a low-resistance material. In the triple squirrel-cage induction motor, the outer layer cage conductor 4 has a peak of torque in a low rotation number region, the intermediate layer cage conductor 5 has a peak of torque in an intermediate rotation number region, and the inner layer cage conductor 6 has a peak of torque in a rating rotation number region. The outer layer cage conductor 4 is formed of phosphor bronze, and each of the intermediate layer cage conductor 5 and the inner layer cage conductor 6 is formed by a copper square bar.

Description

  The present invention relates to a triple squirrel-cage induction motor.

  Conventionally, starting current is reduced, starting torque is increased, unnecessary equipment and wiring are unnecessary, slip at the time of rated operation is reduced, and torque at intermediate time is increased to increase inertial force. Japanese Patent Laid-Open No. 6-205570 discloses an efficient squirrel-cage induction motor capable of reducing heat generation even when a rotating body is driven and a power supply cable is long, enabling frequent start-up.

  A squirrel-cage induction motor presented in this publication includes a stator 2 that forms a rotating magnetic field as shown in FIGS. 4 and 5, a rotor 3 that is rotatably provided inside the stator 2, and An outer layer cage conductor 4 made of a high resistance material provided in the periphery of the rotor 3, an intermediate layer cage conductor 5 made of an intermediate resistance material provided inside the outer layer cage conductor 4, and the middle layer cage And an inner layer cage conductor 6 made of a low resistance material provided inside the shape conductor 5, the outer layer cage conductor 4 has a torque peak in the low rotational speed region, and the middle layer cage conductor 5 is in the middle. A torque peak is present in the rotational speed region, and the inner-layer squirrel-cage conductor 6 has a torque peak in the rated rotational speed region.

  In this triple squirrel-cage induction motor, a secondary current flows through the outer-layer cage-shaped conductor 4 mainly made of a high-resistance material at a stage where the number of revolutions at the time of starting is small and the slip is large. can get. As the rotational speed increases and slip decreases, first, a secondary current mainly flows through the middle-layer cage conductor 5, and a secondary current mainly flows through the inner-layer cage conductor 6 at rated rotation.

  Thus, the combination of the impedances of the outer-layer cage conductor 4, the middle-layer cage conductor 5, and the inner-layer cage conductor 6 makes it possible to reduce the starting current from the initial start to the rated operation, and to reduce the starting current. No voltage starter is required.

  Further, the outer layer cage conductor 4 made of a high resistance material has a torque peak in the low rotation speed region, and the middle layer cage conductor 5 made of a medium resistance material has a torque peak in the intermediate rotation speed region. Since the inner-layer squirrel-cage conductor 6 has a torque peak in the rated rotation speed region, a substantially uniform high torque can be obtained in the entire region including the intermediate region from the low rotation to the high rotation from the initial start to the rated rotation operation. .

  Therefore, even when a conventional triple squirrel-cage induction motor drives a rotating body with a large inertia force, a high torque can be obtained with a small current value in a whole region from the start to the rated rotation, and it can be started in a short time. The amount of heat generated is small, and the activation frequency can be increased. Even when the power cable is long, it can be driven sufficiently with a small-capacity cable because it generates a small amount of heat with a small current.

  Further, in the conventional triple-cage induction motor, the rotor 3 is formed by laminating annular magnetic steel plates such as silicon steel plates, and as shown in FIG. The cross-section of each of the shape conductor 4 and the middle-layer cage conductor 5 is circular, and the cross-section of the inner-layer cage conductor 6 is a rectangle.

JP-A-6-205570

  As described above, the conventional triple squirrel-cage induction motor is extremely efficient. Recently, however, IE3 defined by IEC60034-30 of the international standard IEC (International Electrotechnical Commission) and JISC4034-30 of the Japanese Industrial Standard. (Premium efficiency) prime movers are required.

  This invention is made | formed in view of the point which concerns, and makes it a subject to provide the highly efficient triple squirrel-cage induction motor which can respond to said IE3 (premium efficiency).

  The present invention, which has been made to solve the above-described problems, includes a stator that forms a rotating magnetic field, a rotor that is rotatably provided inside the stator, and a high resistance that is provided at the periphery of the rotor. An outer layer cage conductor made of a material, an intermediate layer cage conductor made of a medium resistance material provided inside the outer layer cage conductor, and an inner layer cage made of a low resistance material provided inside the middle layer cage conductor The outer layer cage conductor has a torque peak in the low rotation speed region, the middle layer cage conductor has a torque peak in the intermediate rotation region, and the inner layer cage conductor has the rated rotation speed. In a triple squirrel-cage induction motor having a torque peak in the region, the outer-layer cage conductor is formed of phosphor bronze, and the middle-layer cage conductor and the inner-layer cage conductor are each formed of a copper square bar. It is characterized in that is.

  Further, in the present invention, the protruding length of the inner-layer cage conductor from the peripheral portion of the rotor is longer than the protruding length of the outer-layer cage conductor and the intermediate-layer cage conductor from the peripheral portion of the rotor. In addition, a cooling slit is formed on the outer peripheral surface of the rotor to improve efficiency.

  As described above, according to the present invention, it is possible to provide an IE3 (premium efficiency) triple squirrel-cage induction motor defined by IEC 60034-30 of the international standard IEC (International Electrotechnical Commission) and JIS C4034-30 of the Japanese Industrial Standard. it can.

The longitudinal cross-sectional view which shows preferable embodiment of this invention. The front view which fractured | ruptured a part of embodiment shown in FIG. FIG. 2 is a partially enlarged partial view of a rotor in the embodiment shown in FIG. 1. The longitudinal cross-sectional view which shows a prior art example. FIG. 5 is a partially enlarged partial view of a rotor in the conventional example shown in FIG. 4.

  1 to 3 show a preferred embodiment of a triple squirrel-cage induction motor according to the present invention. Reference numeral 1 denotes a main body casing, and disk-shaped brackets 12 and 13 at both ends of a cylindrical cylindrical body 11. The rotation shaft 73 is rotatably supported by bearings 71 and 72 at the center.

  An annular magnetic stator 2 is provided on the inner periphery of the cylindrical body 11 of the main casing 1. The stator 2 is composed of a laminated body in which an annular magnetic steel plate 21 such as a silicon steel plate is laminated and pressed by an end plate 26, and windings 8 are arranged in the axial direction along the inner periphery thereof to form a rotating magnetic field. It is like that.

  Inside the stator 2, a rotor 3 made of a cylindrical magnetic body is rotatably provided via a gap 9 and is fixed to a rotary shaft 73. The rotor 3 is formed of a laminated body in which an annular magnetic steel plate 31 such as a silicon steel plate is laminated and pressed by an end plate 36.

  In the present embodiment, as shown in FIG. 3, a groove 35 having a circular accommodation hole 32 and rectangular accommodation holes 33, 34 in three layers is formed on the periphery of the rotor 3 from the outside. Reference numeral 32 denotes an outer-layer cage conductor 4 having a circular cross section made of a high-resistance material, and the accommodation hole 33 is a middle-layer cage conductor 5 having a circular cross-section made of a medium-resistance material. A rectangular inner-layer cage conductor 6 is inserted and connected at both ends by short-circuit rings 28, 29, 30 to form a three-layer cage conductor.

  Slits 321, 331, 341 are formed outside the accommodation holes 32, 33, 34 of the groove 35, and by adjusting the length and width thereof, the magnetic path formed in this portion is adjusted. The torque characteristics of each of the cage conductors 4, 5, and 6 are determined in combination with the material, shape, and the like of each of the cage conductors 4, 5, and 6.

  In the present embodiment, the outer layer cage conductor 4 is made of a high resistance material such as phosphor bronze and is adjusted to have a torque peak in the low rotational speed region. Instead of brass, which is a medium resistance material, it is made of a low resistance material such as copper, and is adjusted to have a torque peak in the region of high rotation speed. Furthermore, the inner-layer cage conductor 6 is made of a low resistance material such as copper, and is adjusted so as to have a torque peak in the high rotation region, and is arranged so as to have a long cross-sectional shape in the radial direction of the rotor. .

  In the present embodiment, since the secondary current mainly flows through the outer-layer cage-shaped conductor 4 made of a high resistance material at a stage where the rotational speed at the start is small and the slip is large, a high torque can be obtained with a small current. As the rotational speed increases and the slip decreases, a secondary current mainly flows through the middle-layer squirrel-cage conductor 5, and the rotational speed further increases and the operation shifts to rated operation. At rated rotation, a secondary current flows mainly through the inner-layer cage conductor 6.

  When the secondary current mainly flows through the middle-layer cage conductor 5 and the inner-layer cage conductor 6 as described above, the cage conductors 5 and 6 are made of a material having a low resistance. As the number increases, the impedance increases, and as a result, the current value decreases as a whole. Therefore, a low voltage starter at the time of starting is not necessary.

  Further, the outer layer cage conductor 4 made of a high resistance material has a torque peak in the low rotation speed region, and the middle layer cage conductor 5 made of a low resistance material has a torque peak in the intermediate rotation speed region and has a low resistance. The inner-layer squirrel-cage conductor 6 made of a material is adjusted so that there is a torque peak in the rated rotational speed region. Therefore, in the entire region including the intermediate region from the low speed to the high speed from the initial start to the rated rotational operation. Can obtain a substantially uniform high torque. In particular, in this embodiment, the intermediate-layer cage conductor 5 made of a square and low-resistance material is used in the intermediate rotation area after starting, and the inner-layer cage conductor 6 can be quickly and efficiently transferred to the inner-layer cage conductor 6 for efficient and high-speed rotation. .

  Therefore, the triple squirrel-cage induction motor according to the present embodiment has a smaller current than the conventional triple squirrel-cage induction motor in all regions from the start to the rated operation even when driving a rotating body with a large inertia force. High torque can be obtained with the value, so that it can be started in a short time, the amount of heat generation is small, and the starting frequency can be increased.

  In addition, in the present embodiment, the protruding length of the inner-layer squirrel-cage conductor 6 is longer than that of other conductors, and the efficiency in the high rotation range is improved.

  Furthermore, in the present embodiment, the cooling slits 23 are formed on the outer peripheral surface of the stator 2 to prevent the efficiency from being lowered due to heat generation.

  DESCRIPTION OF SYMBOLS 1 Main body casing, 2 Stator, 3 Rotor, 4 Outer layer cage conductor, 5 Middle layer cage conductor, 6 Inner layer cage conductor, 8 Winding, 9 Gap, 11 Tubular body, 12, 13 Bracket, 21 Magnetic steel plate , 23 Slit, 26 End plate, 28, 29, 30 Short ring, 31 Magnetic steel plate, 32, 33, 34 Housing hole, 35 groove, 36 End plate, 71, 72 Bearing, 73 Rotating shaft, 321, 331, 341 Slit

Claims (3)

A stator that forms a rotating magnetic field, a rotor that is rotatably provided inside the stator, an outer-layer cage conductor made of a high-resistance material provided at the periphery of the rotor, and an outer-layer cage The outer-layer cage conductor is provided with an intermediate-layer cage conductor made of a medium resistance material provided inside the conductor and an inner-layer cage conductor made of a low-resistance material provided inside the middle-layer cage conductor. In a triple squirrel-cage induction motor having a torque peak in the low speed range, a middle squirrel cage conductor having a torque peak in the middle slewing region, and an inner layer squirrel conductor having a torque peak in the rated speed range ,
A triple squirrel-cage induction motor characterized in that the outer-layer cage conductor is made of phosphor bronze, and the middle-layer cage conductor and the inner-layer cage conductor are each made of a square bar made of copper.   The protruding length of the inner-layer cage conductor from the periphery of the rotor is longer than the protruding length of the outer-layer cage conductor and the middle-layer cage conductor from the periphery of the rotor. The triple squirrel-cage induction motor according to claim 1.   The triple squirrel-cage induction motor according to claim 1 or 2, wherein a cooling slit is formed on an outer peripheral surface of the stator.